Long-term fate of tropical forests may not be so dire

Long-term fate of tropical forests may not be so dire

Tropical rainforests are often described as the “lungs of the earth,” able to essentially inhale carbon dioxide from the atmosphere and exhale oxygen in return. The faster they grow, the more they mitigate climate change by absorbing CO2.

This role has made them a hot research topic, as scientists question what will happen to this vital carbon sink long-term as temperatures rise and rainfall increases.

Our findings fundamentally change a view of the tropical forest carbon cycle that has been published in textbooks and incorporated into models of future climate change for years."

–Philip Taylor

Conventional wisdom has held that forest growth will dramatically slow with high levels of rainfall. But CU Boulder researchers this month turned that assumption on its head with an unprecedented review of data from 150 forests that concluded just the opposite.

“Our data suggest that as large-scale climate patterns shift in the tropics, and some places get wetter and warmer, forests will accelerate their growth, which is good for taking carbon out of the atmosphere,” said Philip Taylor, a research associate with the Institute of Arctic and Alpine Research (INSTAAR). “In some ways, this is a good-news story, because we can expect greater CO2 uptake in tropical regions where rainfall is expected to increase. But there are a lot of caveats.”

Ecologists have long thought that forest growth follows a hump-shaped curve when it comes to precipitation: To a point, more rainfall leads to more growth. But after about 8 feet per year, it was assumed too much water can waterlog the ecosystem and slow the growth rate of forests. While working in the Osa Peninsula of Costa Rica, Taylor, who got his doctoral degree in ecology and evolutionary biology at CU Boulder, began to question this assumption.

“Here we were in a place that got 16 feet of rain per year, and it was one of the most productive and carbon-rich forests on Earth. It clearly broke from the traditional line of thinking,” he said.

Intrigued, Taylor spent four years synthesizing data on temperature, rainfall, tree growth and soil composition from rainforests in 42 countries, compiling what he believes is the largest pan-tropical database to date.

The study, published recently in the journal Ecology Letters, found that cooler forests (below 68 degrees F on average), which make up only about 5 percent of the tropical forest biome, seemed to follow the expected hump-shaped curve. But warmer forests, which are in the majority, did not.

Philip Taylor measures the growth rate of a tropical giant, the Ajo, on the Osa Peninsula in Costa Rica. The trees can grow to 180 feet tall and can live 1000 years.

“The old model was formed with a lack of data from warm tropical forests,” said Taylor, who describes such remote, often uninhabited forests as among the “final frontiers” of scientific exploration. “It turns out that in the big tropical forests that do the vast majority of the ‘breathing’ the situation is flipped. Instead of water slowing growth down, it accelerates it.”

Taylor cautioned this does not mean climate change won’t negatively impact tropical forests at all. In the short term, research has shown, droughts in the Amazon Basin have already led to widespread plant death and a 30 percent decrease in carbon accumulation in the past decade.

“A lot of climate change is happening at a pace far quicker than what our study speaks to,” he says. “Our study speaks to what we can expect forests to do over hundreds of years.”

Because the carbon cycle is complex, with forests also releasing carbon into the atmosphere as plants die, it’s still impossible to say what the net impact of a wetter climate might mean for the forest’s ability to sequester carbon, said senior author Alan Townsend, a professor of environmental studies.

“The implications of the change still need to be worked out, but what we can say is that the forest responds to changes in rainfall quite differently than what has been a common assumption for a long time,” said Townsend.

Going forward, the authors hope the findings will set the record straight for educators and scientists.

“Our findings fundamentally change a view of the tropical forest carbon cycle that has been published in textbooks and incorporated into models of future climate change for years,” said Taylor. “Given how much these forests matter to the climate, these new relationships need to be a part of future climate assessments.”

Related Articles

A new educational partnership at the University of Colorado Boulder will provide expanded degree options for working professionals interested in specialized graduate education focused on energy and water. Beginning this fall, qualified students can earn both a Master of Engineering (ME) degree and a Professional Certificate in Renewable and Sustainable Energy or a Professional Certificate in Water Engineering and Management. The degree and certificates can be earned either via distance education or in campus classes and may be pursued either part- or full-time. Read more

To reflect its broader focus, the Colorado Renewable Energy Collaboratory, a research consortium including the University of Colorado Boulder, the Colorado School of Mines, Colorado State University and the U.S. Department of Energy’s National Renewable Energy Laboratory has adopted a new name: the Colorado Energy Research Collaboratory. Read more

A joint renewable energy center of the University of Colorado at Boulder, Colorado State University, Colorado School of Mines, the U.S. Department of Energy's National Renewable Energy Laboratory and industry has been awarded $336,534 from the National Science Foundation so that undergraduates can conduct research related to the conversion of biomass to fuels and chemicals. Read more